Tropical North Atlantic Response to ENSO: Sensitivity to Model Spatial Resolution

In this study, the ENSO teleconnection with the tropical North Atlantic (TNA) sea surface temperatures (SSTs) in boreal spring is analyzed in ocean-atmosphere coupled global circulation models. To assess the role played by horizontal resolution of models on this teleconnection, we used a multimodel dataset that is the first to combine models with both low and high resolution. The TNA response to ENSO projects onto the most significant SST mode of the tropical Atlantic at interannual time scales, the Atlantic meridional mode (AMM). Its evolution is primarily driven by the wind-evaporation-SST (WES) feedback, which in turn is based on the development of an initial SST gradient. This study examines and quantifies the relative contribution of a dynamic-related (upwelling) and a thermodynamic-related (evaporation) process in triggering this gradient in the case of the ENSO-TNA teleconnection. While no major contribution is found with the evaporation, a consistent contribution from the coastal upwelling off northwest Africa is identified. This contribution is enhanced in high-resolution models and highlights the close link between the upwelling in winter and the development of the AMM in spring. It is further shown that high-resolution models present a thinner and more realistic ocean mixed layer within the upwelling area, which enhances the effect of surface winds on upwelling and SSTs. As a consequence, high-resolution models are more sensitive than low-resolution models to surface wind errors, thereby they do not ensure improved reliability or predictability of the TNA SST response to ENSO.

Automated summary

In this study, the role of the ENSO teleconnection with the tropical North Atlantic sea surface temperatures in boreal spring is analyzed. It is found that the Atlantic meridional mode plays a significant role in this teleconnection. The study also highlights the importance of coastal upwelling off northwest Africa in triggering this teleconnection. Additionally, it is shown that high-resolution models are more sensitive to surface wind errors, but do not necessarily improve the reliability or predictability of the TNA SST response to ENSO.